JP6029796B1 - Power converter - Google Patents

Abstract

The power conversion apparatus 100 includes a power loss estimated value estimated based on a detected value of the output current of the main circuit 102, the temperature of the fin that cools the main circuit 102, the flow rate of the fluid that cools the fin, and the temperature of the fluid. Based on the detected value, the junction temperature of the main circuit 102 associated with the flow rate of the fluid and the load factor of the main circuit 102, or the detected value of the flow rate of the fluid and the output current of the main circuit. Junction temperature estimation unit 104-2 that estimates the junction temperature of the main circuit, junction temperature estimation value estimated by junction temperature estimation unit 104-2, fluid flow rate, load factor of main circuit 102, and junction temperature determination value The display information generation unit 104-3 generates display information to be displayed on the display unit in association with each other and outputs the display information to the display unit.

Description

  The present invention relates to a power conversion device including a power conversion circuit that converts power supplied from a power source and outputs the converted power to a load.

  The conventional power conversion device disclosed in Patent Document 1 is based on a use environment condition in which the state of the power conversion device satisfies a specified life based on a comparison result between the heat sink temperature detected by the heat sink temperature detection unit and the specified heat sink temperature. Or the state of the power converter is determined based on the comparison result between the load factor calculated based on the output current of the power converter detected by the output current detector and the specified load factor. Judgment is made whether the operating environment conditions satisfy the lifetime, and if the power converter status is determined not to be in the operating environment conditions, a signal indicating that the operating condition is outside the operating conditions is output to the outside. It is configured. The power conversion device includes an overcurrent protection function and an overheat protection function as a protection function of the power conversion device in addition to the function of determining whether the state of the power conversion device is in a use environment condition that satisfies a specified life. .

JP 2008-17602 A

  Here, the temperature detected by the cooling fin temperature detection unit may vary depending on the environment in which the power conversion device is installed. As the flow rate per unit time of a fluid such as liquid or gas that cools the cooling fin increases, The temperature detected by a fin temperature detection part shows the tendency to fall. Therefore, in the conventional power conversion device represented by Patent Document 1, in order for the user to check the operable range of the power conversion device, the power conversion device is operated to the rated load or the maximum load in an actual installation environment. Thus, it is necessary to verify whether the power converter overload error or thermal protection does not operate, or whether the power converter does not output an alarm. As described above, in the conventional power conversion device represented by Patent Document 1, not only does it take time to perform a trial operation of the power conversion device in the actual installation environment, but also the selected power conversion device can be applied in the actual installation environment. In order to judge whether or not, specialized knowledge is required. In particular, in order to determine the suitability of the power conversion device in the actual installation environment, it is necessary to take measures such as dispatching an expert to the installation location, and there is a problem that the cost associated with the installation of the power conversion device is increased. .

  This invention is made | formed in view of the above, Comprising: It aims at obtaining the power converter device which can reduce the cost accompanying the installation in an installation environment.

In order to solve the above-described problems and achieve the object, the present invention provides a power conversion device that includes a main circuit that converts power supplied from a power source and outputs the converted power to a load, and a control circuit that controls the main circuit. The control circuit includes: a power loss estimation value estimated based on a detection value of an output current of the main circuit; a temperature of a fin that cools the main circuit; and a flow rate of a fluid that cools the fin When the junction temperature estimation unit that estimates a junction temperature of the main circuit as a junction temperature estimate based on the detected temperature of the fluid, the load factor and the junction temperature determination value of the flow rate and the main circuit before Symbol fluid generates display information for displaying the junction temperature estimate is only pair応付on the display unit, characterized by comprising a display information generation unit for outputting to the display unit.

  The power converter according to the present invention has an effect of reducing the cost associated with installation in an installation environment.

The figure which shows the example which installed the power converter device which concerns on Embodiment 1 of this invention in the outer peripheral surface of the flow path through which a fluid flows. The block diagram of the power converter device which concerns on Embodiment 1 of this invention A flowchart showing operations in the power loss estimation unit, the junction temperature estimation unit, and the display information generation unit The figure which shows typically the thermal circuit model of a power converter The figure which shows the relationship between the thermal resistance between the fluid estimated by the thermal resistance estimation part and the fin, and the flow rate of the fluid The figure showing the example of the junction temperature displayed on the display The block diagram of the power converter device which concerns on Embodiment 2 of this invention The block diagram of the power converter device which concerns on Embodiment 3 of this invention

  Hereinafter, a power converter according to an embodiment of the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram showing an example in which the power conversion device according to Embodiment 1 of the present invention is installed on the outer peripheral surface of a flow path through which a fluid flows. A power conversion apparatus 100 illustrated in FIG. 1 includes a casing 101 that forms an outline of the power conversion apparatus 100, a circuit board 105 installed inside the casing 101, and power that is mounted on the circuit board 105 and supplied from a power source. The main circuit 102 that converts the voltage and outputs it to the load, the control circuit 104 that is mounted on the circuit board and controls the main circuit 102, the heat dissipation fin 106 that dissipates the heat generated in the main circuit 102, and the temperature of the fin 106 And a fin temperature detecting unit 103 for detecting.

  A liquid fluid flows inside the flow path 200, the fluid temperature detection unit 201 installed in the flow path 200 detects the temperature of the fluid, and the fluid flow rate detection unit 202 installed in the flow path 200 detects the fluid flow. The flow rate is detected. The power conversion device 100 according to the first embodiment includes a plate-like heat radiation fin 106, and the fin 106 is brought into direct contact with the flow path 200, so that heat generated in the main circuit 102 is passed through the fin 106 and the flow path 200. In this structure, the heat of the main circuit 102 is effectively dissipated by absorbing the heat into the fluid.

  FIG. 2 is a configuration diagram of the power conversion apparatus according to Embodiment 1 of the present invention. The power conversion device 100 is disposed between the AC input terminal 1A and the AC output terminal 1B, and includes a main circuit 102 composed of a plurality of semiconductor elements, a control circuit 104 that controls the main circuit 102, and a main circuit 102 A current detector 5 that detects an output current, and an output current detection unit 107 that converts a voltage directly proportional to the current detected by the current detector 5 into a voltage that can be handled by the control circuit 104 and outputs the converted voltage. An AC power supply 20 is connected to the AC input terminal 1A, and a load (not shown) driven by the power converter 100 is connected to the AC output terminal 1B.

  The main circuit 102 is connected to the AC input terminal 1A, is configured by a rectifier circuit 2 including a plurality of rectifier diodes and a plurality of switching elements, and converts DC power output from the rectifier circuit 2 into AC power. The inverter circuit 4 that outputs to the AC output terminal 1B, one end is connected to the positive bus between the rectifier circuit 2 and the inverter circuit 4, and the other end is connected to the negative bus between the rectifier circuit 2 and the inverter circuit 4. And a smoothing capacitor 3. Each of the plurality of switching elements constituting the inverter circuit 4 may be a semiconductor element such as a power transistor, a power MOSFET (Metal-Oxide Field-Effect Transistor), or an IGBT (Insulated Gate Bipolar Transistor), or a nitrogen. A wide band gap semiconductor such as gallium or silicon carbide may be used.

  The control circuit 104 is estimated by the power loss estimator 104-1 that estimates the power loss generated in the main circuit 102 based on the current detection value detected by the output current detector 107, and the power loss estimator 104-1. The power loss estimation value, the fin temperature detection value detected by the fin temperature detection unit 103, the fluid flow rate detection value detected by the fluid flow rate detection unit 202, and the fluid temperature detection value detected by the fluid temperature detection unit 201 The junction temperature of the main circuit 102 associated with the fluid flow rate and the load factor of the main circuit 102, or the junction of the main circuit 102 associated with the fluid flow rate and the detected value of the output current of the main circuit 102 Stored in the junction temperature estimation unit 104-2 that estimates the temperature, the determination value storage unit 104-4 that stores the junction temperature determination value, and the determination value storage unit 104-4 Display information to be displayed on the display unit 300 in association with the junction temperature determination value, the junction temperature estimation value estimated by the junction temperature estimation unit 104-2, the fluid flow rate, and the load factor of the main circuit 102 is generated and displayed. Display information generation unit 104-3 to be output to the unit 300. As described above, the control circuit 104 receives the current detection value, the fin temperature detection value, the fluid flow rate detection value, and the fluid temperature detection value as input, and outputs display information. The control circuit 104 includes a signal generation unit that generates a switching signal for controlling on / off of each of the plurality of switching elements constituting the inverter circuit 4 based on the detected current value. The illustration is omitted.

  Junction temperature estimation unit 104-2 calculates the thermal resistance between the semiconductor element constituting main circuit 102 and the fluid based on the power loss estimation value, the fin temperature detection value, the fluid flow rate detection value, and the fluid temperature detection value. , A thermal resistance estimation unit 6 that is estimated in association with the fluid flow rate, a thermal resistance estimation value estimated by the thermal resistance estimation unit 6, a load factor of the main circuit 102 or a detected value of the output current of the main circuit 102, And a temperature estimation unit 9 that estimates the junction temperature of the main circuit 102 associated with the fluid flow rate and the load factor of the main circuit 102 based on the detected fluid temperature.

  Hereinafter, the operation of the power conversion apparatus 100 will be described with reference to FIGS. 3 to 6.

  3 is a flowchart showing operations in the power loss estimation unit, the junction temperature estimation unit, and the display information generation unit, FIG. 4 is a diagram schematically showing a thermal circuit model of the power converter, and FIG. 5 is estimated by the thermal resistance estimation unit. FIG. 6 is a diagram showing an example of the junction temperature displayed on the display unit. FIG. 6 is a diagram showing the relationship between the thermal resistance between the fluid and the fins and the flow rate of the fluid.

  The plurality of switching elements constituting the inverter circuit 4 operate according to the switching signal output from the control circuit 104, whereby the AC power supplied from the AC power supply 20 is converted into DC power, and the DC power is converted into AC by the inverter circuit 4. It is converted into electric power and supplied to the load of the power conversion device 100.

(Step S <b> 1) In the power loss estimation unit 104-1, the power loss that occurs in the main circuit 102 is estimated based on the current detection value during the operation of the main circuit 102. The power loss of the main circuit 102 as a whole is equal to the sum of the power loss caused by a plurality of rectifier diodes constituting the rectifier circuit 2 and the power loss caused by a plurality of switching elements constituting the inverter circuit 4, and is expressed by the following (1 ) Expression. Ptotal is the power loss of the entire main circuit 102, PCONV is the power loss of the rectifier circuit 2, and PINV is the power loss of the inverter circuit 4. The power loss of each of the rectifier circuit 2 and the main circuit 102 can be estimated by calculation or circuit simulation in consideration of factors such as turn-on switching loss, turn-off switching loss, and PWM carrier frequency of the semiconductor element. The method is known and will not be described.
Ptotal = PCONV + PINV (1)

  (Step S <b> 2) The thermal resistance estimation unit 6 estimates the thermal resistance between the semiconductor element constituting the main circuit 102 and the fluid in association with the fluid flow rate. FIG. 4 shows a thermal circuit model of a semiconductor element cooled by a fluid through fins 106. Tr is the fluid temperature and Tfin is the fin temperature. ΔTfin−r is the temperature difference between the fluid and the fin, that is, the temperature rise of the fin.

Tfin is expressed by the following equation (2).
Tfin = ΔTfin−r + Tr (2)

Here, since ΔTfin−r is the amount of temperature rise of the fin, the amount of temperature rise of the fin is expressed by the following equation (3). Rfin-r is a thermal resistance between the fluid and the fin, and Ptotal is a power loss generated in the entire main circuit 102.
ΔTfin−r = Rfin−r × Ptotal (3)

By substituting the above equation (3) into the above equation (2), Tfin is expressed by the following equation (4).
Tfin = Rfin−r × Ptotal + Tr (4)

Rfin-r is expressed by the following equation (5) by modifying the above equation (4).
Rfin−r = (Tfin−Tr) ÷ Ptotal (5)

  Note that ΔTc−fin shown in FIG. 4 is a temperature difference between the case enclosing the chip of the semiconductor element and the fin, that is, a temperature rise amount of the case of the semiconductor element, and ΔTj−c is This is the temperature difference from the case, that is, the amount of temperature rise of the chip. ΔTc−fin is obtained from the thermal resistance between the case and the fin and the power loss generated in the main circuit 102, and ΔTj−c is the thermal resistance between the case and the chip and the power loss generated in the main circuit 102. It is obtained by.

  The thermal resistance estimation unit 6 calculates a fin temperature increase amount corresponding to the difference between the fluid temperature detection value and the fin temperature detection value, and the semiconductor element and the fluid are calculated based on the calculated temperature increase amount and the power loss generated in the main circuit 102. Is estimated in association with the fluid flow rate.

  FIG. 5 shows the relationship between the thermal resistance Rfin-r estimated by the thermal resistance estimation unit 6 and the fluid flow rate. The horizontal axis represents the flow rate of the fluid, and the vertical axis represents the thermal resistance Rfin-r. The thermal resistance estimation unit 6 estimates, for example, a thermal resistance Rfin-r when a specific flow rate A is measured and a thermal resistance Rfin-r when a flow rate B lower than the flow rate A is measured. The thermal resistance estimation unit 6 estimates the thermal resistance Rfin-r indicated by the solid line, that is, the thermal resistance Rfin-r corresponding to the flow rate, by linearly interpolating between the two estimated thermal resistances Rfin-r.

  As described above, the thermal resistance estimation unit 6 uses the measurement results at several points to correspond the thermal resistance Rfin-r to the flow rate of the fluid without operating the power converter 100 to a load condition such as a rated load or a maximum load. To estimate.

  (Step S3) Next, the temperature estimation unit 9 calculates the load factor of the main circuit 102 based on the current value detected by the output current detection unit 107, and the calculated load factor and the thermal resistance estimation unit 6 estimate the load factor. Based on the estimated value of thermal resistance and the detected fluid temperature, the amount of increase in junction temperature is calculated. Specifically, for example, the ratio of the current detection value to the rated current value is calculated as the load factor by dividing the current detection value by the rated current value set in the temperature estimation unit 9 in advance. The temperature estimation unit 9 uses the current value detected by the output current detection unit 107 instead of the calculated load factor, and calculates the junction temperature based on the current value, the thermal resistance estimation value, and the fluid temperature detection value. A configuration for calculating the amount of increase may also be used.

  (Step S4, Step S5) The temperature estimation unit 9 changes the calculated load factor value, and calculates the power loss value corresponding to the load factor value and the thermal resistance estimation value estimated by the thermal resistance estimation unit 6. And the junction temperature of the main circuit 102 associated with the fluid flow rate is estimated. Specifically, the temperature estimation unit 9 compares the estimated junction temperature estimated value with the junction temperature determination value. When the junction temperature estimated value is higher than the junction temperature determination value (step S5, No), the temperature estimation unit 9 estimates the junction temperature by reducing the load factor. In addition, when using the current value detected by the output current detection unit 107 instead of the calculated load factor, the temperature estimation unit 9 responds to the fluid flow rate based on the power loss value corresponding to the current value and the thermal resistance estimation value. The junction temperature of the attached main circuit 102 is estimated. Specifically, the temperature estimation unit 9 compares the estimated junction temperature estimated value with the junction temperature determination value, and is detected when the junction temperature estimated value is higher than the junction temperature determination value (step S5, No). Reduce the current value and estimate the junction temperature.

  When the junction temperature estimated value is lower than the junction temperature determination value (step S5, Yes), the display information generation unit 104-3 performs the process of step S6. Even when the junction temperature estimated value is higher than the junction temperature determination value, for example, the temperature estimation unit 9 obtains the junction temperature estimated value after linear interpolation by linearly interpolating between the two estimated junction temperature estimated values. be able to. Based on the estimated junction temperature value after linear interpolation, the temperature estimation unit 9 can estimate a junction temperature value lower than the junction temperature determination value. Therefore, even when the junction temperature estimated value after linear interpolation is lower than the junction temperature determination value, the display information generation unit 104-3 performs the process of step S6.

  (Step S6) FIG. 6 shows an example of the junction temperature displayed on the display unit 300. The horizontal axis represents the load factor, and the vertical axis represents the junction temperature. The determination value shown in FIG. 6 is a junction temperature determination value. FIG. 6 shows the junction temperature corresponding to each of the three flow rates A, B, and C. The junction temperature corresponding to each of the flow rates A, B, and C is lower than the determination value when the load factor ranges from 0% to 50%. Therefore, it can be seen that the power conversion apparatus 100 can be operated up to a load factor of 50% at any of the flow rates A, B, and C. However, when the load factor is in the range from 50% to 70%, the junction temperature corresponding to the flow rate A exceeds the determination value, and therefore the power converter 100 is difficult to operate at the load rate of 50% or more at the flow rate A. I understand. Moreover, in the range from 70% to 100% of the load factor, the junction temperature corresponding to each of the flow rates A and B exceeds the judgment value, so that the power converter 100 has a load factor of 70% or more at the flow rates A and B. It turns out that driving is difficult. Further, according to the display example of FIG. 6, it is possible to determine how much margin the chip junction temperature for each load factor has or is insufficient with respect to the determination value. As described above, according to the power conversion device 100 of the first embodiment, the junction temperature that is equal to or lower than the determination value or higher than the determination value is visualized and displayed on the display unit 300 for each operation condition such as fluid flow rate, fluid temperature, and load factor. Thus, the user can confirm the range in which the power conversion device 100 can operate, the range in which the operation is difficult, and the operation conditions. In addition, when the junction temperature estimated value after linear interpolation is calculated | required in the temperature estimation part 9, the display information production | generation part 104-3 is the junction temperature estimated value after a linear interpolation, junction temperature judgment value, the flow volume of fluid, and the main circuit 102. Are displayed on the display unit 300 in association with each other. As described above, according to the power conversion device 100 of the first embodiment, the junction temperature that is equal to or lower than the determination value or higher than the determination value is visualized and displayed on the display unit 300 for each operation condition such as fluid flow rate, fluid temperature, and load factor. Thus, the user can confirm the range in which the power conversion device 100 can operate, the range in which the operation is difficult, and the operation conditions.

  In the above-mentioned conventional technology, whether the power converter is operated to the rated load or the maximum load under the actual installation environment, the power converter overload error or thermal protection does not operate, or the power converter does not output an alarm. It was necessary to verify whether or not. In particular, when the power converter is a water cooling system, the flow rate of the fluid for cooling the cooling fins changes, so that the cooling capacity varies depending on the environment in which the power converter is installed. Therefore, in order to determine the load range in which the power converter can operate, after installing the power converter in the actual installation environment, there are no overload errors in various operation patterns, There is a problem in that it is necessary to verify whether a temperature abnormality occurs, and the cost associated with the installation of the power converter is increased.

  In contrast, power converter 100 according to Embodiment 1 can easily confirm the operable range of power converter 100 without operating up to the rated load or the maximum load. Moreover, in the power converter device 100 according to the first embodiment, the operable range of the power converter device 100 is displayed on the display unit 300. Therefore, even if a specialist is not dispatched to the installation location of the power converter device 100, The user can easily confirm the operable range of the power conversion device 100, and can suppress an increase in cost associated with the installation of the power conversion device 100.

Embodiment 2. FIG.
FIG. 7 is a configuration diagram of the power conversion device according to the second embodiment of the present invention. In the second embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, description thereof is omitted, and only different parts are described. In power conversion device 100A of the second embodiment, control circuit 104A is used instead of control circuit 104 of the first embodiment, and fluid temperature detection unit 201, fluid flow rate detection unit 202, and junction temperature estimation unit of the first embodiment are used. Instead of 104-2, a fluid temperature setting unit 201A that sets the temperature of the fluid, a fluid flow rate setting unit 202A that sets the flow rate of the fluid, and a junction temperature estimation unit 104-2A are used. The control circuit 104A according to the second embodiment inputs the current detection value, the fin temperature detection value, the fluid flow rate setting value, and the fluid temperature setting value, and outputs the display information.

  Junction temperature estimation unit 104-2A calculates the thermal resistance between the semiconductor elements constituting main circuit 102 and the fluid based on the estimated power loss value, the detected fin temperature value, the fluid flow rate setting value, and the fluid temperature setting value. , A thermal resistance estimation unit 6 that is estimated in association with the fluid flow rate, a thermal resistance estimation value estimated by the thermal resistance estimation unit 6, a load factor of the main circuit 102 or a detected value of the output current of the main circuit 102, And a temperature estimation unit 9 that estimates the junction temperature of the main circuit 102 associated with the flow rate of the fluid and the load factor of the main circuit 102 based on the fluid temperature set by the fluid temperature setting unit 201A. In the second embodiment, it is possible to easily confirm the operable range of the power conversion device 100 without using the fluid temperature detection unit 201 and the fluid flow rate detection unit 202, so that further cost reduction can be achieved. It is.

Embodiment 3 FIG.
FIG. 8 is a configuration diagram of a power conversion apparatus according to Embodiment 3 of the present invention. In the third embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, description thereof is omitted, and only different parts are described.

  The power conversion device 100B shown in FIG. 8 uses the control circuit 104B instead of the control circuit 104 of the first embodiment, and instead of the fluid temperature detection unit 201 and the fluid flow rate detection unit 202 of the first embodiment, A fluid temperature input unit 201B for inputting temperature information and a fluid flow rate input unit 202B for inputting fluid flow rate information are provided. A controller 400 that controls the temperature and flow rate of the fluid is connected to the fluid temperature input unit 201B and the fluid flow rate input unit 202B. The control device 400 includes a fluid temperature detection unit 401 that detects the fluid temperature and a fluid flow rate detection unit 402 that detects the flow rate of the fluid, and the fluid temperature detected by the fluid temperature detection unit 401 is fluid as fluid temperature information. The fluid flow rate input to the temperature input unit 201B and detected by the fluid flow rate detection unit 402 is input to the fluid flow rate input unit 202B as fluid flow rate information.

  In the third embodiment, the control of the fluid temperature and flow rate is basically performed by the external control device 400. Therefore, the result of the fluid temperature and flow rate controlled by the control device 400 is input to the power conversion device 100B. By doing so, it is possible to reduce the cost by reducing the fluid temperature detector and the fluid flow rate detector in the power converter 100B.

  In the first, second, and third embodiments, the inverter circuit is used as the main circuit 102. However, the power converters of the first, second, and third embodiments may use a converter circuit as the main circuit 102. . In the first, second, and third embodiments, the temperature and flow rate of the liquid fluid are detected and the junction temperature is estimated. However, the fluid is not limited to the liquid but is a gas such as air or refrigerant gas. May be. In the first, second, and third embodiments, the junction temperature determination value stored in the determination value storage unit 104-4 is used. However, the junction temperature determination value may be input directly from the outside of the power conversion apparatus 100.

  As described above, the power conversion devices according to the first, second, and third embodiments provide the estimated power loss based on the detected value of the output current of the main circuit, the temperature of the fin that cools the main circuit, and The junction temperature of the main circuit associated with the flow rate of the fluid and the load factor of the main circuit based on the flow rate of the fluid that cools the fins and the temperature detection value of the fluid, or the flow rate of the fluid and the main circuit Junction temperature estimation unit for estimating the junction temperature of the main circuit associated with the detected value of the output current, the junction temperature estimation value estimated by the junction temperature estimation unit, the flow rate of the fluid, the load factor of the main circuit, and the junction temperature A display information generation unit configured to generate display information to be displayed on the display unit in association with the determination value and output the display information to the display unit; With this configuration, it is possible to easily check the operable range of the power conversion device without operating the power conversion device to the rated load or the maximum load. In the power converters according to the first and second embodiments, since the operable range of the power converter is displayed on the display unit 300, the user can be sent without taking measures such as dispatching an expert to the place where the power converter is installed. Can easily check the operable range of the power converter, and can suppress an increase in cost associated with the installation of the power converter.

  In addition, the power conversion devices according to Embodiments 1, 2, and 3 store the junction temperature estimated value estimated by the junction temperature estimation unit, the fluid flow rate, the load factor of the main circuit, and the junction temperature determination value in association with each other. The display unit may include a storage unit, and the display information generation unit may output the junction temperature estimated value, the fluid flow rate, the main circuit load factor, and the junction temperature determination value stored in the storage unit to the display unit. With this configuration, estimation results of a plurality of junction temperatures having different refrigerant temperatures and flow rates are stored, which makes it easier for the user to study appropriate refrigerant conditions.

  The configuration described in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and can be combined with other configurations without departing from the gist of the present invention. It is also possible to omit or change the part.

  1A AC input terminal, 1B AC output terminal, 3 smoothing capacitor, 4 inverter circuit, 5 current detector, 6 thermal resistance estimation unit, 9 temperature estimation unit, 20 AC power supply, 100 power conversion device, 100A power conversion device, 100B power Conversion device, 101 housing, 102 main circuit, 103 fin temperature detection unit, 104 control circuit, 104-1 power loss estimation unit, 104-2 junction temperature estimation unit, 104-2A junction temperature estimation unit, 104-3 display information Generation unit, 104-4 judgment value storage unit, 104A, 104B control circuit, 105 circuit board, 106 fin, 107 output current detection unit, 200 flow path, 201 fluid temperature detection unit, 201A, 201B fluid temperature input unit, 202, 202A, 202B Fluid flow rate input unit, 300 display unit, 400 control device , 401 fluid temperature detecting unit, 402 the fluid flow detector.

Claims (8)

A power conversion device including a main circuit that converts power supplied from a power source and outputs the converted power to a load, and a control circuit that controls the main circuit,
The control circuit includes:
The estimated power loss estimated based on the detected value of the output current of the main circuit, the temperature of the fin that cools the main circuit, the flow rate of the fluid that cools the fin, and the detected temperature of the fluid A junction temperature estimator for estimating the junction temperature of the main circuit as a junction temperature estimated value based on ,
It generates display information for displaying the load factor and the junction temperature determination value paired応付only was the junction temperature estimation value of the flow rate and the main circuit before Symbol fluid on the display unit, generates display information to be output to the display unit And
A power conversion device comprising: The display information generation unit
The display information for generating the junction temperature estimation value less than the junction temperature determination value and the junction temperature estimation value equal to or higher than the junction temperature determination value on the display unit is generated. Power conversion device. A storage unit for storing the junction temperature estimation value estimated by the junction temperature estimation unit, the flow rate of the fluid, the load factor of the main circuit, and the junction temperature determination value in association with each other;
The display information generation unit outputs the estimated junction temperature value, the fluid flow rate, the load factor of the main circuit, and the junction temperature determination value stored in the storage unit to the display unit. The power converter device described in 1. The junction temperature estimator is
A power loss estimated value estimated based on a detected value of the output current of the main circuit, a fin temperature detected value detected by a fin temperature detecting unit installed in the fin, and a fluid flow rate for detecting a flow rate of the fluid The junction temperature of the main circuit is estimated based on the fluid flow rate detection value detected by the detection unit and the fluid temperature detection value detected by the fluid temperature detection unit that detects the temperature of the fluid. The power conversion device according to claim 1. The control circuit includes:
The current detection value detected by the current detection unit that detects the output current of the main circuit, the fin temperature detection value, the fluid flow rate detection value, and the fluid temperature detection value are input, and the display information is output. The power conversion device according to claim 4, wherein: The junction temperature estimator is
Estimated power loss estimated based on the detected value of the output current of the main circuit, detected fin temperature detected by the fin temperature detector installed on the fin, and fluid flow setting for setting the fluid flow rate The junction temperature of the main circuit is estimated based on a fluid flow rate setting value set by the unit and a fluid temperature setting value set by the fluid temperature setting unit for setting the temperature of the fluid. Item 4. The power conversion device according to Item 1. The control circuit includes:
The current detection value detected by the current detection unit that detects the output current of the main circuit, the fin temperature detection value, the fluid flow rate setting value, and the fluid temperature setting value are input, and the display information is output. The power conversion device according to claim 6, wherein: A power conversion device including a main circuit that converts power supplied from a power source and outputs the converted power to a load, and a control circuit that controls the main circuit,
The junction temperature of the main circuit is estimated as the junction temperature estimate, load factor and junction temperature determination value paired応付only was the junction of the flow rate and the main circuit of the fluid for cooling the fins attached to the front SL main circuit A power converter that displays an estimated temperature value on a display unit.

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